Nonlinear Magnetic Gradients and Complete Magnetic Geometry From Multispacecraft Measurements

Topological configurations of the magnetic field play key roles in the dynamics of space plasmas. This study presents a novel algorithm that can estimate the quadratic magnetic gradient as well as the complete geometrical features of magnetic field lines, based on magnetic field and current density measurements by a multiple spacecraft constellation at four or more points. The explicit estimators for the linear and quadratic gradients, the apparent velocity of the magnetic structure and the curvature and torsion of the magnetic field lines can be obtained with well-predicted accuracies. The feasibility and accuracy of the method have been verified with two demonstrations. The algorithm has been successfully applied to exhibit the geometrical structure of a flux rope. This algorithm has wide applications for studying a variety of magnetic configurations in space plasmas.

Automated summary

The study presents a novel algorithm that can estimate the quadratic magnetic gradient and complete geometrical features of magnetic field lines with high accuracy. The algorithm's feasibility and accuracy have been verified through two demonstrations, showing successful application in exhibiting the geometrical structure of magnetic fields in space plasmas. This algorithm has wide applications for studying various magnetic configurations in space plasmas.